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Microwaves and Antenna Engineering Research Group

Pioneering the analysis, design and integration of high frequency electronics devices and systems

Revised Marshal Listing:

Cables/connectors – Zain/Yuepei/Qassim

VNA/cal kits – Panos/Spiros/Kostas

Severs/computers – Haris/Kostas

USRPs – Yuan/Yuepei/Alex

Small Electronics – Alex

Oscilloscope – Spiros/Panos/Simonne

Spectrum Analyzer – Cristian

MXG/Signal generators – Spiros/Penny

Far-field/Horn Antennas – Victoria/Rahil/ Yuepei

Near-field/NSI probes – Victoria/Salva/Yuepei

Solder Stations / 3D Printer – Panos/Spiros

Rules 

Maintain a safe and well organized lab for all:
• Continue to follow our EMP Gmail booking system whenever using the lab. This includes stations, large and small equipment items. Going forward, we should also book-out ALL cables, connectors, adapters, and simulation computers. Basically the aim is to have a fully electronic log booking system. This makes it very easy to find which individual used equipment last, should it be misplaced and where to find it.
• Lab access and key card system. Speak with Yuan, and Symon.
• It is the supervisors responsibility to ensure compliance of the lab rulesMaintain a safe and well organized lab for allContinue to follow our EMP Gmail booking system whenever using the lab. This includes stations, large and small equipment items. Going forward, we should also book-out ALL cables, connectors, adapters, and simulation computers. Basically the aim is to have a fully electronic log booking system. This makes it very easy to find which individual used equipment last, should it be misplaced and where to find it.Lab access and key card system. Speak with Yuan, and Symon.

It is the supervisors responsibility to ensure compliance of the lab rules.

As a reminder, it is the marshal’s responsibility and all lab users to make sure our equipment list is updated. Please take a moment to review the google drive folder and add new equipment that is relevant and delete any old items. This includes connectorized amplifiers, mixers, etc. It is everyone’s responsibility to make sure our online inventory is representative of the lab.

There are number of marshals who have excellent working knowledge of the various RF equipment in the lab. If you are not familiar with the equipment – no problem – please kindly ask and get one of the marshals to assist and give some direction as needed. Please remember that all the RF measurement/instrumentation equipment is very expensive, and it is privilege to have access for your projects and research.   

 

 

 

 

EPSRC iCase Studentship with Renishaw

EPSRC iCase Studentship with Renishaw Plc. This is available for Home and EU applicants who have lived, worked or studied within the UK for three years prior to the start date. The studentship is for 4 years and covers University tuition fees (Home/EU) and provides an annual tax-free stipend of minimum £17,000 (increasing each year).The expected start date is 1st October 2019.  

Project Description

RF/microwave components are essential for telecommunications and radar systems. With on-going development of 5G mobile networks and new generations of satellite platforms, which are the backbone of many emerging applications such as Internet-of-Things (IoT) and Internet-of-Space (IoS), metal 3D printing or additive manufacturing has recently been seen as an enabling technology for future RF/microwave components to meet stringent requirements for system applications. 

Additive manufacturing (AM) is revolutionising how RF/microwave components are designed and manufactured. This all presents a great opportunity and potentially large market of using and commercializing metal 3D printing technology in this field. This industrially collaborative PhD will provide students with the opportunity to interact with researchers and developers from both academic and industry sectors. It is expected that the candidate will work on industry inspired problems and challenges. The project will involve electromagnetic simulation and design of metal 3D RF/microwave components, prototype hardware manufacturing and experimental demonstration. 

The project industrial partner Renishaw is one of the world’s leading engineering and scientific technology companies, with expertise in precision measurement and healthcare. The company supplies products and services used in applications as diverse as jet engine and wind turbine manufacture, through to dentistry and brain surgery. It is also a world leader in the field of additive manufacturing (also referred to as metal 3D printing), where it is the only UK business that designs and makes industrial machines which ‘print’ parts from metal powder. For this project, the company will also offer Additive Manufacturing of prototype on their machines; their commitment of appropriate human resource and use of their ancillary equipment to support research; and a member of staff to be an industrial supervisor and liaison.This project will further strengthen the Strategic Alliance between Renishaw and Heriot-Watt. 

References

[1] IET Microwaves, Antennas&Propagation, “Microwave components using AM techniques”, vol.11(14), 2017. 

[2] Sorrentino R. and Peverini O.A., “Additive manufacturing: A key enabling technology for next generation microwave and millimeter-wave systems,” Proceedings of the IEEE, vol. 104, pp. 1362–1366, 2016. 
[3] Booth P. and Lluch E.V., “Enhancing the Performance of Waveguide Filters Using Additive Manufacturing”, Proceedings of the IEEE, vol. 105, pp. 613-619, 2017. 
[4] Zhang B. and Zirath H.,“Metallic 3D printed rectangular waveguides for millimeter-wave applications,” IEEE Trans. on Components, Packaging and Manufacturing Technology, vol. 6, pp. 796–804, 2016.

Please do not hesitate to contact me if you have any enquiry or need more information.

A formal application can be mad online at

https://www.hw.ac.uk/study/apply/uk/postgraduate.htm

15 Funded Early Stage Researcher (ESR) PhD positions in H2020-MSCA-ITN-TESLA

Applications are now closed

Space is key asset for Europe. Europe’s citizens enjoy the benefits, from jobs and economic growth, to public services, efficient communications and security. To respond to global challenges, Europe must continue to have a prominent role in space at a time when other world powers are rapidly developing their space capabilities. Since satellite payload RF components and systems are essential for delivering mission objectives and supporting ground equipment and telecommunication systems, new technologies and techniques are required to respond to emerging satellite applications and technology challenges. To this end, TESLA Innovative Training Network (ITN), a consortium of 8 academic universities and 11 industrial partners, will train 15 PhD students, i.e. Early Stage Researcher (ESR) fellows, in a vibrant, multidisciplinary training-through-research environment uniquely equipped to develop the Advanced Technologies for future European Satellite Applications. The TESLA ESR fellows will pursue PhD in collaborating with senior staff in academic and industrial sectors to conduct top-notch research into new and enabling technologies for satellite flexible payloads, big constellation systems and Internet of Space, satellite high-speed communications and remote sensing, as well as large satellite platforms.

Research topics include: 

  • Highly integrated compact lightweight switch matrix technology 
  • (Scientist-in-Charge Prof. Jiasheng Hong, J.Hong@hw.ac.uk)
  • New design techniques of space systems suitable for metallic additive manufacturing technologies in the context of the IoS
  • (Scientist-in-Charge Prof. Miguel Laso, mangel.gomez@unavarra.es)
  • Millimetre-wave components for high-power space applications
  • (Scientist-in-Charge Prof. Miguel Laso, mangel.gomez@unavarra.es
  • Synthesis and design of reconfigurable topologies for high-power filters and multiplexers
  • (Scientist-in-Charge Prof. Vicente Boria, vboria@dcom.upv.es)
  • Novel technologies for miniaturized passive components and sub-systems with tuning capabilities 
  • (Spain, Scientist-in-Charge Prof. Vicente Boria, vboria@dcom.upv.es
  • Millimetre wave hardware for the next generation W band satellite communication systems
  • (Scientist-in-Charge Prof. Michael Höft, Michael.Hoeft@tf.uni-kiel.de)
  • Synthesis, design and fabrication of novel tunable components for satellite communication
  • (Scientist-in-Charge Prof. Michael Höft, Michael.Hoeft@tf.uni-kiel.de
  • Micromachined millimetre and submillimetre-wave filters for communication satellites and space-born remote sensing
  • (Scientist-in-Charge Prof. Joachim Oberhammer, joachimo@kth.se
  • 3D micromachined micromechanics for low-loss, low-weight re-configurable satellites 
  • (Scientist-in-Charge Prof. Joachim Oberhammer, joachimo@kth.se)
  • Additive manufacturing of non-planar microwave passive components 
  • (Scientist-in-Charge Prof. Wolfgang Bösch, wbosch@tugraz.at 
  • Design of mm-wave passive components in semi-planar technology 
  • (Scientist-in-Charge Prof. Wolfgang Bösch, wbosch@tugraz.at)
  • High performance miniaturized component for aerospace applications
  • (Scientist-in-Charge Prof. Cristiano Tomassoni, cristiano.tomassoni@unipg.it)
  • Use of additive manufacturing (AM) for microwave components for space applications up to terahertz frequencies
  • (Scientist-in-Charge Prof. Cristiano Tomassoni, cristiano.tomassoni@unipg.it)
  • Advanced materials for high power components
  • (Scientist-in-Charge Prof. Nicolas Delhote, nicolas.delhote@xlim.fr)
  • Development of topology optimization tools for RF components
  • (Scientist-in-Charge Prof. Nicolas Delhote, nicolas.delhote@xlim.fr)

Essential Criteria and Important eligibility rules for candidates: 

Applicants should have a good undergraduate degree or a postgraduate Master's degree (or equivalent) in electronic or electrical engineering or a physical sciences subject as well as highly proficient English language skills. The ability to thing logically, create solutions and make informed decisions is essential as are excellent organizational skills and the ability to travel and work across Europe.

There are no restrictions on the nationality, but researchers must be early-stage researchers (ESR), i.e. at the time of recruitment, be in the first four years (full-time equivalent research experience) of their research careers and have not been awarded a doctoral degree.

Researchers must comply with the mobility rule - Researchers may not have resided or carried out their main activity (work, studies, etc.) in the country of their host organisation for more than 12 months in the 3 years immediately before the reference date: the recruitment. Compulsory national service and/or short stays such as holidays are not taken into account.

Salary: The successful candidates will receive an attractive salary in accordance with the MSCA regulations for Early Stage Researchers http://ec.europa.eu/research/mariecurieactions. The PhD funding is for 36 months.

Application: Contact the Scientist-in-Charges at the host organizations for individual ESR positions as soon as possible for further details. (NB. the expected start date of 1st July, 2019 or as mutually agreed upon by both parties)

Skills/Qualifications: Applicants should have a good undergraduate degree or a postgraduate Master's degree (or equivalent) in electronic or electrical engineering or a physical sciences subject as well as highly proficient English language skills. The ability to thing logically, create solutions and make informed decisions is essential as are excellent organizational skills and the ability to travel and work across Europe.

Requirements: There are no restrictions on the nationality, but researchers must be early-stage researchers (ESR), i.e. at the time of recruitment, be in the first four years (full-time equivalent research experience) of their research careers and have not been awarded a doctoral degree.

Researchers must comply with the mobility rule - Researchers may not have resided or carried out their main activity (work, studies, etc.) in the country of their host organisation for more than 12 months in the 3 years immediately before the reference date: the recruitment. Compulsory national service and/or short stays such as holidays are not taken into account.

Electromagnetic sensors for wearable healthcare applications

 

Dimitris St

Wearable electronics technology for healthcare management, personal safety, and consumer products enhancement has the potential to transform our everyday life and improve the quality of living of healthcare patients and athletes. Non-invasive healthcare monitoring of body signal bio-parameters – such as movements, respiration, and temperature – without physical intervention or interaction with the patient is particularly of interest in this project. To date, the widespread adoption of many body wearables is limited due to intrinsic limitations mainly related to the flexible/rigid interface: complex wiring, mechanical/electrical reliability, presence of rigid and bulky batteries and charging circuits, washability. Seamless integration is key for user convenience that will ultimately lead to adoption of the technology in everyday applications.  This PhD research project envisages developing a wireless body sensor reader that can detect and estimate human body signals through a passive radio-frequency interrogation process and will be integrated with a sensing antenna. It is expected that this PhD research project will change the conventional approach to wearable healthcare electronics, ultimately leading to novel RF circuit architectures that take advantage of modern System-on-a-Package and System-on-a-Chip technology developments, and it may be a key enabler in lowering healthcare costs, particularly for the elderly.

Eligibility: DTP (UK nationals, or EU citizens who lived in the UK for the past 3 years)

Interested potential PhD candidates, please contact Prof Dimitris Anagnostou for enquires. Applicants should apply by Friday 26th June through the Heriot-Watt University portal.

 

Dr. Symon Podilchak, Heriot-Watt University, UK 

Title: Time Reversal Techniques by retrodirective antenna arrays for Wireless Power Transfer 

Abstract: Retrodirective antenna arrays have certain capabilities that can offer some very interesting advantages for wireless power transfer. This includes real-time, automatic target tracking by time reversal and re-radiation of RF power to a specific direction away from the array, and without previous knowledge of the original target location. The workshop will investigate these concepts in the frequency and time domains while also considering practical examples such as the charging of a mobile unit in the far-field using efficient antennas and high-power microwave circuit technologies. 

Bio: Dr. Symon K. Podilchak completed his PhD at Queen’s University in Canada and is now an Associate Professor at Heriot-Watt University in Edinburgh, Scotland. His research is currently supported by a H2020 Marie Skłodowska-Curie European Research Fellowship. He is also registered Professional Engineer (P.Eng.) and has had industrial research experience designing automotive radar systems for Samsung and Magna Electronics. Some recent industry experience also includes the design of new wireless power transmission systems using time reversal techniques for mobile handhelds. His research interests also include planar antennas, retrodirective arrays, and microwave circuits. Dr. Podilchak has been the recipient of many best paper awards and scholarships; most notably Research Fellowships from the IEEE Antennas and Propagation Society, as well as, the IEEE Microwave Theory and Techniques Society. He also received The Best Paper Prize for Antenna Design at the 2012 European Conference on Antennas and Propagation, The 2013 Postgraduate Fellowship from the Natural Sciences and Engineering Research Council of Canada (NSERC), and The 2016 European Microwave Prize for his PhD research, which also, received The Outstanding Dissertation Award from Queen’s University in 2014.

 

Prof. George Goussetis, Heriot-Watt University, UK 

georgeBio: George Goussetis (S-99, M-02, SM-12) received the Diploma degree in Electrical and Computer Engineering from the National Technical University of Athens, Greece, in 1998, and the Ph.D. degree from the University of Westminster, London, UK, in 2002. In 2002 he also graduated B.Sc. in physics (first class) from University College London (UCL), UK. 

In 1998, he joined the Space Engineering, Rome, Italy, as RF Engineer and in 1999 the Wireless Communications Research Group, University of Westminster, UK, as a Research Assistant. Between 2002 and 2006 he was a Senior Research Fellow at Loughborough University, UK. He was a Lecturer (Assistant Professor) with Heriot-Watt University, Edinburgh, UK between 2006 and 2009 and a Reader (Associate Professor) with Queen’s University Belfast, UK, between 2009 and 2013. In 2013 he joined Heriot-Watt as a Reader and was promoted to Professor in 2014. He has authored or co-authored over 400 peer-reviewed papers five book chapters one book and four patents. His research interests are in the area of microwave and antenna components and subsystems. 

Prof. Goussetis has held a research fellowship from the Onassis foundation in 2001, a research fellowship from the UK Royal Academy of Engineering between 2006-2011 and European Marie-Curie experienced researcher fellowships in 2011-12 and again in 2014-17. He is the co-recipient of the 2011 European Space Agency young engineer of the year prize, the 2011 EuCAP best student paper prize, the 2012 EuCAP best antenna theory paper prize and the 2016 Bell Labs prize. He serves as Associate Editor to the IEEE Antennas and Wireless Propagation Letters.

In August, 2018 Prof. Goussetis became Head of Institute, Institute of Sensors, Signals & Systems at Heriot-Watt University.

Prof. Apostolos Georgiadis, Heriot-Watt University, UK 

Title: Energy harvesting and wireless power transfer for RFID and wireless sensors: from circuit optimization and signal design to ambient RF backscattering 

Abstract: Backscatter communication and RFID technology provides a foundation, an enabling technology towards the realization of ‘zero-power’ wireless sensors and implementing the Internet-of-Things (IoT) and machine-to-machine (M2M) communication. Interest in RFID technology is further enhanced by its fundamental capability for wireless powering of devices, allowing for battery-less operation. The presentation begins with an overview of ambient energy availability and energy harvesting technology challenges for low power circuits and sensors. Design challenges and novel technologies and materials, such as paper, textiles, and inkjet/3D printing are highlighted. Special focus is placed on electromagnetic energy transfer and harvesting for range maximization of passive RFID systems. Rectenna design and optimization under different operating conditions and in different operating frequencies from HF to millimeter waves is addressed. Multiple technology harvesters leading to the development of energy harvesting assisted RFIDs are discussed. Low profile and conformal solar antennas and solar–electromagnetic harvesters including examples implemented on paper and textile substrates are presented. The integration of an antenna with a thermo-electric generator is demonstrated. Waveform optimization in wireless power transfer is addressed, and the ability to improve the RF-DC power conversion efficiency of electromagnetic energy harvesting devices by tailoring the characteristics of the transmitted signals is discussed. The last part of the talk presents application examples including RFIDs and wireless sensors powered from solar and electromagnetic energy harvesting, millimeter wave back-scattering, solar energy harvesting for RFID tags and sensors based on ambient RF signal backscattering. 

apostolosBio: Apostolos Georgiadis was born in Thessaloniki, Greece. He received the Ph.D. degree in electrical engineering from the University of Massachusetts, Amherst, in 2002. He is Honorary Associate Professor at Heriot-Watt University, Edinburgh, UK. He has been involved for more than 20 years in the field of RF/microwave wireless systems. His research interests include energy harvesting and wireless power transmission and inkjet and 3D printed electronics. He was Associate Editor of the IET Microwaves Antennas and Propagation Journals, IEEE Microwave and Wireless Components Letters and the IEEE RFID Virtual Journal. He serves as an Associate Editor of the IEEE Journal on RFID and he is the founder and Editor in Chief of the Wireless Power Transfer journal by Cambridge University Press. He is a EU Marie Curie Global Fellow. He is Member of the IEEE MTT-S TC-24 RFID Technologies (past Chair) and Member of IEEE MTT-S TC-26 Wireless Energy Transfer and Conversion. He is Chair of URSI Commission D, Electronics and Photonics and Vice President of Conferences of the IEEE Council on RFID. He has published more than 180 papers in peer reviewed journals and international conferences. In 2016 his proposal for Inkjet/3D printed millimeter wave systems received the Bell Labs Prize, 3rd place among more than 250 proposals recognizing ideas that 'change the game' in the field of information and communications technologies.